SoLID DAQ A.Camsonne SoLID collaboration meeting November 8 th 2013
Outline Experiment requirements PVDIS Calorimeter trigger and readout PVDIS setup,event size and data rates GEM electronics SRS SIDIS event size SIDIS electronics layout MRPC electronics Budget Test stand To do list Conclusion
Experiment requirements PVDIS – Pion contamination – Trigger rate 30 KHz max per sector – 30 independent sectors SIDIS – Trigger rate 60 KHz coincidence e pi 100 KHz singles
Calorimeter trigger
PVDIS calorimeter readout Need new development of SD and FADC firmware 100 K$ for R&D and prototyping
PVDIS calorimeter trigger Send data from one sector to the neighboring sector
PVDIS setup Shower : 1830 channels Preshower : 1830 channels Light Gas Cerenkov : 270 channels GEM : 4700 strips Trigger : Shower and Cerenkov Rate with 30 ns gate : 3e6 * 200e3 * 30e-9= 18 KHz Rates estimate for 20 KHz
Event size PVDIS Assume 2 high energy cluster in each sector and all Cerenkov firing for each trigger Data rates at 20 KHz = 56 MB/s DetectorChannels fired Event size KB EC Cerenkov90.36 GEM Total2.78
SRS
Switch SRS – Cheaper per channel cost – Less crates – Higher data transfer rate
SIDIS Detectors – Forward Calorimeter preshower + shower Scintillator Light Gas Cerenkov Heavy Gas Cerenkov – Large Angle Calorimeter shower Scintillator – GEM 5 planes
SIDIS, J/Psi requirements SIDIS : 60 KHz coincidence e/pi, 80 KHz singles J/psi : triple coincidence e, e+,e- Plan – FADC integrated readout – GEM with deconvolution one sample readout In theory should be able to reach 100 KHz
Event size SIDIS GEM occupancy with deconvolution : 1.2 KBytes Other detectors : ~ 1.9 KBytes Data rate 100 KHz with 3.1 Kbytes event size 310 MB/s Could take more but need reduce with L3
SIDIS, J/psi Calorimeter electron trigger as PVDIS Send cluster number to GTP Coincidence APV25 : on chip convolution one sample readout FADC readout : zero suppress 10 % MIP for calorimeter readout time and integral Might consider waveform for SPD and preshower depends on final trigger rate
SIDIS trigger Electron trigger – Shower + LC + SPD + MRPC : Forward angle – Shower + SPD : Large angle Pion trigger – Shower + HC + SPD – Shower J/psi trigger – Shower ( 3 clusters above threshold ) + LC + SPD + MRPC
SIDIS electronics layout
Electronics layout SIDIS
FADC occupancy
MRPC Question about electronics and funding Solution in house / commercial electronics – 2 input registers : 2K$ – 4 V1290 CAEN High Resolution TDC : 11 K$ – Price per sector : 44 K$ – Total price : 1.4 M$ ( only readout no FE ) – Funding request from Tsinghua University – Either use this solution or develop custom module
DAQ cost estimate ModuleUnit price K$NumberTotal (K$) FADC ,269.5 TD CTP SSP GTP5.015 TS3.51 TID SD VXS crate SRS computer VME CPU Total2,844.8
Additionnal cost 100 K$ R&D prototyping SD 50 K$ shield house electronics Total around 3 M$
L3 Farm Base on Hall D estimate – Driven by PVDIS – Assuming 30 KHz 390 cores for non tracking option 1500 cores with tracking
Operation costs Cables : 300 K$ Racks : 15 K$ Tape : 600 K$
Test stand Test trigger logic Test max trigger rates Test electronics with real detector signals Test GEM readout max performance 4 FADC, 1 CTP and 2 VXS crates 1 SRS from UVA and 1 INFN MPD readout
Things needed for director review Tes trigger logic and FADC performance PVDIS – Occupancy in Calorimeter – L3 data reduction scheme SIDIS trigger rates – MRPC, LGC, HC, SPD simulation Simulation digitization SIDIS GEM occupancy from G4 SIDIS rates from G4 simulation MRPC development custom electronics APV25 high rate, test with SRS L3 reduction factor and ressource needed test algorithm MaPMT test
Conclusion PVDIS doable and cost reasonable now calorimeter rate down : 18 KHz SRS : saves cost on crates and per channel, more performant data transfer GEM event size manageable SIDIS most like should be able to take all single triggers by reading only integral and one sample per trigger for GEMs Need to test at high rate